Jig for assembling hollow structures



Jan 11, 1949- w. L. LEwls ETAL 2,458,788

JIG FOR ASSEMBLING HOLLOW STRUCTURES Filed Jan. 18, 194s e sheets-sheen 1 57 'u Z :lo

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Y JIG FOR ASSEMBLING HOLLOW STRUCTURES Filed Jan. 18, 1943 6 Sheets-Sheet 3 IIIIIIMII 'lllll II".-

| L 4a 67 6/ 65 64 6 62 4o 44 42 //'4 40x/f5 N21 @5 @6 441 FOR THE FIRM Jari. 11, 1949. WL.v Ewl-S ETA; 2,458,788

JIG FOR SSEMLING HOLLOW STRUCTURES Filed Jan. 18, 1943 O 6 Sheets-Sheet 4 /N VEN TOR:

W/LL/AM L. Ew/J FREDEQ/c C. DAHL Arrow/VE )(5 Jan. 11, 1949. W, LEWS ET Ag 2,458,788

J IG FOR ASSEMBLING HOLLOW STRUCTURES Filed Jan. 18; 1943 e sheets-sheet 5 /N VENTO/P6 WML/AM L. Ew/5 FEEDER/c C. PAHL .5y HAR/Q16, K/ECH, F df @AR/PA:

FOR THE FIRM A Traag/E YJ Jan. v11, 1949. w. LEwls l-:TAL 2,458,788

JIG FOR ASSEMBLING HOLLOW STRUCTURES Filed Jan. 18, 1943 4 6 Sheets-Sheet 6 Y Z/ (ORA-farne ATToaQ/VEYJ Patented `an. 11, 1941@ ASSEMBLING HOLLOW STRUCTURES William L. Lewis, Giena Culver City, Calif.;

y J IG `FOR ale, and

Frederic C. ram,

said Pahl Aassigner to Hughes Tool Company,

poration of Delaware Houston, Tex., a cor- Application January 18, 1943, Serial No. 472,804

Our invention relates to procedures for assembling and fabricating structures, withspecial reference to hollow structures having wall material in sheet or plate form reinforced by frame `members extending along the inner or outer surface of the wall material. a means and a method for properly positioning or assembling the various parts of the structure and for uniting the structurally related parts.

For the purpose of disclosure, our invention is described herein as appliedkto the fabrication of certain airplane parts', with special reference to monocoque construction, but'it kwill be apparent that the invention is likewise applicable to the building of other structures including vehicle bodies, boats, and the like. yOur description is also directed specifically to so-called plastic construction in which construction the material employed may include laminated wood, impregnated wood, or various plastics, the parts being united by suitable glue or plastic cement. It will be noted, however, that certain features of the invention have utility in solving assembly vproblem-s regardless of the materials used and regardless of the'methods of uniting the parts. n

The general object of the invention is to provide a method and means for positioning structural parts, for example, frame members vand sheet material, in positions for assembly and to provide a method and means for subsequently applying pressure or pressure and heat to unite the positioned structural parts.

Various expedients have been employed'in the prior art to locate and temporarily x frame members to receive sheet material; In the present invention as applied to this'task we propose to provide a novel jig or mandrel assembly having important advantages over the prior art expedients. Some of the objects of our new procedure, with special reference to the employment of such a mandrel assemblyVinclude the following: to provide a mandrel assembly that will afford eicient internal support for a hollow grouping of frame members and sheet material;y to provide a mandrel assembly that may be readily withdrawn after the frame members and sheet material are united; to provide a mandrel assembly that will adequately support an exceptionally long tubular shell and yet permit continuous circumferential frame members or frame rings to be slipped over the mandrel assembly for distribution to assembly positions; to provide a mandrel assembly that may be readily built .up or expanded for internal bracing of surroundingjcircumferential frame members and yetl becon- 2 claims. 1 (ci. 14A- 281) The invention is directed to l formation about the the lperiphery of the assembly.

. 2 e tracted `or collapsed for subsequent withdrawal; to provide a mandrel assembly that includes at least one key element, which'element or elements maybe withdrawn longitudinally to cause the mandrel assembly to contract or collapse for subsequent removal; to providev a mandrel assembly of separate elements designed to be held together by temporary connections until circumferential frame members are positioned thereon and thereafter to be held'together solely by compression on the part of the circumferential `frame members, whereby Ithe temporary connections may be removed to permit subsequent withdrawal of the elements individually; 't'o'provide a mandrel assembly'with the'foregoing features that may be rotated about itsl longitudinal axis for the convenience of craftsmen; and to provide such a mandrel assembly in combination with jig attachments whereby fittings may be located or assembled ron a completed hollow body before the'hollow body Ais removed from the mandrel assembly.l

When glue of the type satisfactory for this work is used to unite structural parts, pressure must be applied within a short period of time after the glue is deposited on the' surfaces to be joined. Iftheglue is thermal setting, both pressure and heat may` bey applied within the time interval. Heretofore the prevalent method of pressing sheet material against an assemblage of frame members, to cause vthe parts to unite by the setting of intervening glue, has been to apply straps or girth members to the sheetA material, the required pressure being obtained by placing the straps or girth members under tension. Serious disadvantages arey inherent in such a method. The tightening ofthe friction means to attain the required pressure is so'time-consuming that a relatively extensive shell with a relatively large number of'frame members cannot be prepared forthe gluing operation within the time limit imposed by the glue. The placing of the straps or girth members under tension affords no inamount of radial pressure produced. Because of friction a strap or girth member tends when tightened to create circumferential stresses `in a manner to distort the assembly. Likewise because of friction between the strap or girth member and the sheet material the pressure exerted may not'be uniform around If the hollow body thatis beingfconstructed is oval or elliptical in cross section, a strap or girth member cannot act to apply uniform radial pressure against the sheet material. It is well known that straps or girth members of the type usually employed tend to expand with increasing temperature and consequently reduce the radial pressure against the sheet material when heat is applied `to set the glue. A further disadvantage is that once an assembly equipped with fstraps` or iginth members is placed in aheating chamber orautoclave, no adjustments may be made thereafter to regulate the radial pressure against the sheet material by the straps or girth members.

We propose to avoid these disadvantages by mounting pressure members adjacent .the sheet material and then placing lu'idpressure .expansile means between the =pressure 'members ,and

the sheet material to expand and thereby exert pressure against the sheet material. The objects of our invention with respect to -such-apressure procedure include the following: to provide a pressure member in combination with an expansile uid .duct thereby to apply localized pressure against the underlying sheetmaterial; 'to provide such a combination in which 'theexpansiletduct conforms to Vthe 4pattern of VVframe members against which' pressure is exerted; to provide a combination of numerous Vpressure vmembers and expansile ducts all .of which maybe made effective easily within the time limit'imposed by the properties of the glue employed; to provide such a combination in the 'form'oi a-split ,ring that may bequickly mountedover ,a Sheet metal shell; to provide such a combinationior exerting substantially uniform circumferential pressure against a non-,circular shell; to `provide .such a combination for Ause -.in a heating chamber together with means for 'indicating and controlling the applied pressure from a 4,point .outside the chamber; to provide such a combination 2in .which the fluid for .applying ,pressureis heated".for heat transfer to the glue, .thereby to avoid .the necessity of using a .heating chamber; to incorporate in such a combination an electric heatingfelement .conforming tothe Vpatternof theglue as analternative arrangement for avoiding thenecessity of using a heating chamber.

Further objects and advantages of .our .invention including objects relating .to .special problems involved in vfabricating conicalhollow bodies will beapparent -in Athe .following-.detailed Idescription, taken with the accompanying .drawings In theA drawings, v.which are to -beconsidered `as illustrative only:

Fig. 1 isa perspective View .of the.partiallyas sembled mandrel assembly .together A.with .supporting structure;

Fig. 2 is asimilar .View on a llargerscaleoi `.the mandrel assembly ata more fadvanced-stage-oi assembly, only the `forward portion of the assembly being shown;

Fig. 3 is a similar view showing sheet material in the process of being clampedfaround the mandrel assembly;

Fig. 4 -is a full range perspective :viewlsimilar to Fig. 1 showing the hollow structure completed and illustrating the initial stepsin the vremoval e ofthe mandrel assembly;

Figs. 5to 13 are diagrammatic views *in-side elevation illustrating successive steps in onepractice of our invention;

Fig. 14 is a `fragmentary view similar to Fig. "5 Y' showing the structure modified for producing a hollow body of cylindrical rather `than 'conical configuration;

Fig. 15is across-sectional view showing means surrounding the mandrel assembly to press sheet' indicated by the .43, respectively.v

.struction shown, the .core may be ,ed .pin .5l -that is slidinglymounted .standard `V42 to selectively engage material radially inward against frame members on the assembly;

Fig. 16 is an enlarged fragmentary section taken as indicated by the line It-i6 of Fig. 15;

Fig. 17 is a more or less diagrammatic view showing means tor circula'tinglheated fluid under pressure 'through'a sheet-clamping means;

Fig. 18 is a cross section taken as indicated by the line I 8 l8 of Fig. 17;

Fig. 1-9 lis a :View similar to Fig. 18 illustrating another modified ipractice of the invention;

Fig. .20 is a fragmentary view partly in section and. partly .in side Lelevation illustrating a modi- [ed `practice vof the invention;

Fig.v21.isa-.fragmentary cross section taken as line 2|-2I of Fig. 20;

Fig.22 isa view partly in section and ,partly in side ielevation of an apparatus for applying the principles of the invention to the construction of a tapered nosefor a fuselage, the View showing circumferential pressure rings;

Fig. 2`3:is a similar View with the ,circumferential pressure `rings replaced "by longitudinal pressurel members;

Fig. j24 is .atransverse section taken .as indicated .by theline 1211+211 of Fig. 234;

LFig...2,5 is an enlarged detail of Fig.'244;

`Fig.,.26 'is a `iperspective .view .of aportion .of a .fuselage frame as prepared 'for fthe application .ofl's'heets or ,plates thereto;

`Fig..'27 isa diagrammatic View of an assembly inaheatingchamber with means controlled 'from .the exterior of `the ,chamber for applying iluid pressure .to .the assembly;

Fig..28 isa cross section ofapparatusor applying theprinciples of the .invention .to Ithe construction .of a double-walled conicalstructure;

.29 ,is .an :enlarged detail `of Fig. $28,; .and

.,Fig. 301s a .fragmentarysectional View showing ya .furtherstep .in ythe.construction .of .the conical ,structure .in Figf28.

Figs. .l .to 13 relate to the construction ,cfa boomfor .an aircraft rof ,a .well .known .type .having two such boomsl spaced .on .opposite .sides l,of .the fuselage to support .rearward .tail structure. It is .apparent `from `the figures .that .the boom )is '.ellipticalcor .ovalin ,general cross-.sectional ,con- .figuration .and .tapers from. its .for-ward .end .to a .rear Aportion that extendslaterally for `juncture .with the tail structure .ci .the airplane.

Figs. 1 and 5 illustrating anearlystage vin .the

.fabricatingprocedure show a mandrel .assembly Y,that .ispartially assembled as required for `initially .receiving ,fram e members ,of the boom. The 4construction includes Ya ,base frame 40 that .is mountedcn suitable casters A! .and carries-three remos/.able `.pedestals or standards, .a .forward .standard 4.2 an Yintermediate .standard .43, and arcar.standard 44, .the pur-pose of thestandards being .torotatablysupport an Aaxialccre 45. The core `4 5 is preferably. of` .tubular .construction .and

.by a short .Shaft so. extendsforward from the rear .at `.its rear lend '5U Vretractallly .standardM into a suitable .bearingsocket (not shown) inthe .end ,of the core 4.5. In ,the con- 4latched .against rotationatselected positions by .means .ora-head.-

in theiorward holes .52 in .a Iradial iiangei on the aX'ialcore.

Various jigs .and ixtures maybe Iadded to .the structure as desired. VVFigfl shows a forward jig ra second 55 inthe forni of a rectangular frame that is removably mounted on the base frame 40 by legs B andis further supported by an arm 51, the arm being held in proper position by a pair of spaced parallel angle-irons 58 on the forward end of the core 45.

Figs. l and 5 show certain elements of the mandrel assembly that are initially mounted on the core 45 to ycomplete the major portion of the vertical ,dimension of the assembly. These elements include two diametrically opposite longitudinal elements 80 and 6I which may comprise plates of wood reinforced or thickened by vertical andhorizontal ribs 62. In the present arrangement these two longitudinal elementsare intended to Abe retractable, and'since they are preferably tapered in longitudinal configuration to favor such withdrawal they will for convenience be referred to as the tapered elements 60 and 6I of the mandrel assembly. The tapered elements 60 and Bl terminate short of the intermediate standard 43 to provide clearance for that standard. To continue the desired configuration of the mandrel assembly between the intermediate standard 43 and the rear standard 44 we provide pair of tapered elements 63 and 64 conforming in position and configuration to the tapered elements 60 and 6I.

On the lower edges of the tapered elements 6I and 64, respectively, we place longitudinal mandrel elements 65 and 86 provided with suitable recesses 81 for positioning and retaining circumferential frame members of the boom structure. To hold ythis initial assembly of elements together, suitable temporary fastening expedients may be employed. In our preferred practice we use a series of metal straps 10 onopposite sides of the core 45, the metal straps being shaped to conform to the core. and being temporarily secured by various bolts 1| that extend through the core and through the associated elements.

An early step in the procedure is to disengage the rear standard 44 from the core 45 by retraction of the shaft 50 to permit circumferential frame members or rings 12 of the desired boom structure to Vbe slipped over the smaller end of the mandrel assembly, as shown in Fig. 5. At this time the core 45 is supported by the forward standard 42 and the intermediate standard 43. The rear standard 44 is then again engaged with the core 45 by replacement of the shaft 50, and theintermediate standard 43 is removed to permit the circumferential frame members 12 to be distributed .to positions indicated by the recesses 61, the various Vparts then being in the positions indicated in Fig. l6.

The next step consists of adding to the assembly longitudinal mandrel elements 13 and 14 that are positioned on the upper edges, respectively, of the tapered elements 50 and 63 to complete the vertical dimension of the mandrel assembly, these longitudinal elements 13 and 14 being provided with recesses 15 corresponding to the previously mentioned vrecesses 61. Fig. 7 has two of the forward circumferential frame members 12 broken away to show how the recesses 61 engage the rings at lower points and how the recesses 15 engage the rings at upper points. The forward circumferential frame members or rings 12 on the uniformly tapered portion of the boom are thusanchored in place, while three rearward circumferential frame members designed for cooperation with the tail structure of the airplane at thisl time merely hang in the recesses 15. The longitudinal Aelements 13 and .14are'moved into the desired positions by iirst inserting them longitudinally alongside the core 45 inside the circumferential rings 12, and then moving them laterally upward and rotating them into place. To secure them in position, suitable supplemental straps 11 and additional bolts 18 may be employed, as best shown in Fig. 2.

Each of the circumferential frame members or rings 12 of the boom is thickenedl in radial dimension in the regions of the upper recesses 61 and again in the regions of the lower recesses 15, and in each of these regions is reinforced on each face by a small plate 80, as best shown in Fig. 2. In these reinforced regions of the upper recesses 15 and the lower recesses 81 the rings 12 extend radially outward from the recesses 15 and 61, and the protruding portions of the rings are in turn cut away to provide longitudinally aligned recesses 8l. The purpose oi these ring recesses is to receive an upper longitudinal frame member 82 and to receive a lower longitudinal frame member 83, which frame members are to be structural parts of the completed boom. These longitudinal frame mem-bers 82 and 83 may be simply nailed or otherwise mechanically attached to the rings 12 of the boom. As may be noted in Figs. 8 and 9, the lower longitudinal frame member 83 terminates in a downwardly curved portion 85 that is connected to a rearwardly eX- tending member 86. The rearward member servesV both the purpose of a longeron and the purpose of a plate to receive fittings by which the boom is to be attached to the tail structure of the airplane. The member B3 is mechanically connected to the three rearward rings 12.

The next step in the procedure of building up the mandrel assembly is to add a plurality of elements to complete the assembly in a second dimension, the second dimension being horizontal in Fig. 2. A feature of our invention is the concept that this additional plurality of elements of the mandrel assembly may be so expanded outwardly against the various boom rings 12 as to cause the Whole mandrel assembly to be held in place solely by compression from the rings. When such a condition is achieved, the various metal straps 10 and 11, together with the associated bolts 1I and 18, may be removed, thereby making it possible subsequently to withdraw various elements of the mandrel assembly individually after the fabrication procedure is completed.

As best shown in Fig. 2, the additional plurality of elements for building up the second dimension of the mandrel assembly in the desired manner may consist of a series of plates 81 generally semicircular in coniiguration together with a series of small wedges 88. The plates 81, which are cut to conform to the boom rings l2, are placed inside the boom rings as indicated in Figs. 2 and l5, and are secured in place by the small wedges 88. The various wedges 88 are driven between the inner edges of the plates and the adjacent surfaces of the various tapered elements 68, 6I, 83, and 84 and also Ibetween the inner edges of the plates and the adjacent surfaces of the longitudinal mandrel elements S5, B6, 13, and 14. It is important to note that all of the small wedges 88 are pointed in the same direction as the tapering of the associated tapered elements so that withdrawal of the tapered elements at the end of the fabricating procedure will act to retract the small wedges and thereby loosen the semi-circular plates 81. The expanding action on the mandrel assembly achieved by inserting the small wedges 88V is Suiiicient to place the mandrel assembly -underaconsiderable compressionby .the surround .the supplemental straps 'd'1' may nowfbe removed.

Now thatmall'the .circumferential and longn tuclinal frame members -of the boom Structure are rigidly fixed .1in .their proper :positions for assembly, the nextastepuis to applyglue Ato the -frame members atvall suriacesfof 4juncture:"With theboom shell Aand thenA to apply-.sheet lmaterial tothe frame members with suitablelpressure; the 'pressure being sustained 4duringltlieperiod in Whiohthe-gluesets. It isfapparent'thatthe described mandrel .assemblyhas `utilityliniitselfland may -be employed withv Various expedients old-and `nevv forplaoing the sheet-material under'prlessure. In our preferredpractice,-ihoweverfkweem- `.ploy pressure members adjacent `the lsheet material in combination wthuid pressure-lmeansvbetvveen the pressure members andnthesheetfmatelrial, the iluid pressure means.beingxexpansile-to 'create the required pressureuagainst Altie-sheet material.

`Such a combination oi' pressure lmfemberand :expansile means may, las best Y shownliin4 1 Ei'gs. 3, .15, and 16, be inthe forni-of ha pressureringnor girth member generally .designated S thatlis of split construction so that it Amay be `op'enedand moved laterally into eng-agement withthe assembly. In our preferred-construction=each "of lthe split `rings fell is made in two sections SLT-Which `section may be pivotally interconnected in Iany suitable manner. n thepresent 'arrangement the sections are interconnected 'bytwov quickacting latches` generally designated 92.

Each of the quick-acting latches 32 includes a toggle lever 33 on .one of the sectionsl iinL-the pressure rings Si), are in proper *positionirregis'ten ing with each other,'fthey"may be quickly linterconnected by engaging and "throwingthetoggle levers 93.

As shown in cross-section 1in. Fig. 16, thepresl sure rings or girth members 90 'may be constructed of laminated'wod and formedwith inner circumferential grooves or 'recesses'll in which are placed expansileducts [02 of rubber brother -suitable material. Each 'ducts liner |03 of suitable leXi-blernaterial'that entends around the inner circumference of'thep'ress'ure ring. The liner H13 serves to keep the duct-|02 in place and yet permits the duct to -eXpa'ndf-in- H12 hasialsllll'ply tube ld (Fig. 15) and each 'duct liesla'gainst a wardly toward the laxis foi the pressure ringfil..

A liner liS of woven fabric instead "of rubberor 'the like is preferred for embracing "alshll of conical vor tapering conguration, since a girth member compressing a shell of suchconguration tends to move in the direction'of the-shellta'per and Woven material resists'this tendencyto--an eiective degree.

The s'heetmaterial forformingthe shelllof the boom may be preformed-or not and mayeither be initially applied to form theV entire shell/or may be initially `applied in part. `In` our 'preferred practice the sheet material is preformed 'into What may be termedsemi-cylin'clrical shell sections'fand one of the two shell 'sectionsis"completely asterc'onneetf the upper tapered elements 6u arid-e3 fand-'to `'intereo'n'nec't` the lower tapered members "61 'an'dllll "t is :apparent that vthis operation `oi interconnecting tthe tapered' elements maybe per- 'form'ed any-"time aft-er the metal strapio'anufthe `supi5lemental straps {1]1 are removed.

AThe pressure 'rings"'90"are now removed 'to perniitt'hefremaiin'g-peripheral surfac'esof the circumferential frame members "112 to `be'co'ateil 'ifth'glue and to' permit a second "shell section Av1 08 to'ibe added," thereby Vto complete "the shell 'df 'the fboom. Y"Toreceive thefs'econ'd shellise'ctidn "M8, "the 'mandrel assembly is rt'ated'to placethe iirst Sh''ll 'selion"'lff5"on"t1e underside arid thl'by permttne Asecond shlIsectiOnfto be added :frm above. "Wh'enthe secorid shell Vsection I'U'S'fis 'in placethepressure rings-"'50 are again'dis'tributed on "the :assemblage in 'positions corresponding'to 'thef'conceafled circumferential frame ymembers l2 al'f'gaillthe 'ase'lblage is llOVedv into the htin'g' chamber for' vheat Vandpres'sure treatment. the 'pressure *beingapplied 'by introducing -fluid 'into `'the' A'dlts 1112.

` v`-vv'he'n theessemblage is 'ta-ken fromthe'heat- 'ing dharnb'ertne secontime; lthe pressure 'rings :Sllfare 'removed andthe rsecond "shel'lsection IUE is `'la'ilevd "or otherwise attached 'to "the'lld'rlyifh'g 'longtuimal trane "members "-'z Vane @83. TThe mandrel assembly may then be rotated to its initial position and the forward jig 55 mounted in place to locate holes for forward fixtures H (Fig. 4). At this time other jig 'accessories may be employed, such as the jig generally designated I I I in Figs.v1 and 4, this second jigbeing used to locate fixtures I I2 that are to be later associated with the tail structure of the airplane.

The next task is -to remove the completed 'boom structure. In preparation for this task, the weight ofthe assemblage is transf-erred to a cradle generally designated H3 which comprises a series of transverse plates H4 of wood interconnected by -timbers H5. After` the weight of the structure is transferred `to the cradle as indicated in Fig. 12, steps are taken to cause the mandrel assembly to contract or collapse to permit withdrawal of the separate elements of the mandrel assembly. In our preferred arrangement we provide two special pull rods H6 that are mounted by brackets H1 on the mandrel core 45, there being one pull rod for the uppertapered element 60 and a second pull rod for the lower tapered element 6| of the mandrel assembly. Each of the pull rods H6 is adapted to be attached to the corresponding tapered element by a cross pin H8 (Fig. 1) that removably extends through a 'pair of ears |20 on the end of the tapered element. Each pull rod is slidably mounted in the corresponding bracket H1 and is extensively threaded 'to receive a suitable nut |2| on the outer side of the bracket. When the pull rods H6 are connected to the tapered elements 60 and 6| of the mandrel assembly, the tapered elements may be withdrawn sufficiently to loosen the whole mandrel assembly by the simple procedure of screwing the nuts onto the pull rod, thereby shifting the pull rods longitudinally outward.

After the pull rods H6 have loosened the tapered elements 60 and l|I, as indicated in Fig. 13, the tapered elements may be freely withdrawn. Fig. 4 shows the two tapered elements withdrawn to such an extent as to loosen the grip of the mandrel assembly on the core 45 so that the core may be withdrawn. In Fig. 4 the core is in the initial stages of being so withdrawn. It is to be noted that the forward tapered elements 60 and 6| are connected, respectively, to the corresponding rearward tapered elements 63 and v|54 through the previously mentioned connecting members |01 to move in unison. It is also to be noted that the small wedges 88 are pointed in the same direction as the tapered elements 60, 6|, 63, and -64 so that withdrawal of the tapered elements tends to loosen the small wedges. It is to be further noted that since the tapered elements participate in both the vertical dimension and the horizontal dimension of the mandrelassembly, complete withdrawal of the tapered elements causes the mandrel assembly to collapse across both dimensions. After such collapse, the elements of the mandrel assembly may be removed individually until finally the completed boom is unencumbered and ready for removal from the cradle H3.

The purpose of the diagrammatic Fig. 14 is 'to indicate how the mandrel assembly may be modified to serve as means for fabricatingv an extensive cylindrical shell of substantially uniform diameter. It will be noted that the modification consists essentially of substituting longitudinal mandrel elements |23 and |24 for the previously mentioned longitudinal mandrel elements 13 land 14, the substituted longitudinal elements being tapered complementary to the tapered configuration of the underlying tapered elemen-ts 60 and 63. In the same manner, tapered longitudinal mandrel elements (not shown) are substituted for the lower tapered elements =65 and 66 of the first described arrangement to build up the required uniform diameter.

The fluid employed in 'the iiuid pressure expansile ducts |02 in the pressure rings 80 may be either gaseous or liquid, and a further feature of our invention is that such fluid may be heated, and, if necessary, circulated through the ducts |02 for the purpose of supplying the heat required in. the setting of thermal-setting glue.

In Fig. 17 we show, by way of example, a pressure ring generally designated |25 that is adapted for the circulation of heated fluid. The expansile duct |26 in one of the two sections |21 of the pressure ring |25 has an inlet extension |28 at one end and an outlet extension |30 at the other end. The outlet extension |30 is connected by suitable means |3| to an inlet extension |32 of an expansile du-ct |33 in the other ring section |21, rand this second expansile duct has a discharge extension |35. As indicated in Fig. 18 heat transference from the two expansile ducts |26 and |33 may be facilitated by using a metal liner |36 for the pressure ring linstead of the previously described rubber liner.

vAny suitable system may be used to heat land circulate uid through the pressure ring |25. The arrangement shown in Fig. 17 is designed for heating and circulating water. The system includes a boiler or water heater |31 connected by a suitable pipe |38 to the inlet extension |28 of the pressure ring and a low pressure reservoir |40 connected by a pipe |4| to the discharge extension |35 of the pressure ring. A suitable.A pump |42 draws fluid from the low pressure reservoir |40 through a pipe |43 and delivers the iiuid under pressure to the boiler through a pipe |45. A by-pass |46 from the discharge side of the pump to the low pressure reservoir is provided with a pressure regulating valve |41 that permits the fluid to be by-passed in a manner to maintain a predetermined pressure, which pressure may be indicated by a suitable gauge |48.

Fig. 19 shows a modification of the preferred form of our invention that consists of substituting a heating band |50 for the previously described fabric liner |03 of a pressure ring 90. The heating band |50 comprises an electri-cal resistance or heating element |5| in an asbestos casing.r |52 and is designed to supply the heat required for thermal-setting glue. It will be noted that such a heating band conforms 'to the concealed frame structure to which sheet material is to be bonded.

In the first described practice of our invention the shell sections |05 and |08 are nailed or other- Wise mechanically fastened to the underlying longitudinal frame members 82 and 83. The purpose of Figs. 20 and 21 is to indicate how longitudinal pressure members |53 may be employed to bond the sheet material to the longitudinal members by glue. In the arrangement shown in Figs. 20 and 21, special pressure rings |55 are employed, the split ends of which are circumferentially removed from the regions of the previously mentioned longitudinal frame elements 82 and 83. Since the construction is easily understood in viewl of what has been said before, only the lower longitudinal frame mem-ber 83 is shown in the two figures and only thelower portion of the special pressure ringsv |55. The longitudinal to a pipe 2|| that extends through thechamber wall 2|2 and is provided with a suitable pressure gauge 2|3 on the outside of the wall. lThe pipe 2| is connected to a high pressure pipe 2|5 controlled by a valve 2 I6 and is likewise connected to a relief pipe 2|1 controlled by a valve 2|8. The operator may manipulate the two valves 2||i and 2|8 to control pressure in the pressure rings 256 as guided by the pressure gauge 2|3 and may control the heat in the chamber 2 l2 as guided by a temperature indicator 220 that is remotely controlled by a thermal-responsive element 22| in the heating chamber. One feature of this arrangement is that any tendency of fluid pressure in the pressure rings to drop by reason of thermal expansion of the pressure rings may be ascertained by simply obse-rving the pressure gauge 2 3 and may be corrected by proper manipulation of the valve 2|6.

Figs. 28, 29, and 30 teach how our invention may be applied to the problem of forming a conical shell having numerous external circumferential frame members or rings as distinguished from internal frame members. The particular hollow structure to be formed is a double-walled conical unit to be employed as part of a so-called spinner construction associated with the airplane propellers. The configuration of the unit may be understood from Fig. 28 which shows an inner wall 225 conical in general configuration, an outer wall 226 of similar configuration indicated in dotted lines, and a plurality of circular frame members 221 that serve as annular means interconnecting the two Walls. Eachof thelcircular frame members 221 comprises an inner ring 228, an outer ring 230, and an annular web 23| interconnecting the two rings.

In the procedure for fabricating such a vdoublewalled unit the inner wall 225 is first formed as two halves or shell sections, as heretofore suggested, and the two preformed shell sections are placed on a solid conical mandrel 232, as indicated in Fig. 28. The prefabricated circular frame members 221 are then placed in proper order over the two shells to be acted upon by a series of pressure ring-s generally designated 233.

Each of the pressure rings 233 is made in two semi-circular sections, as heretofore described, and each of the two sections is supported by one or more arms 235 that extend radially inwardly from. surrounding frames 236, there being two such frames adapted to move apart to receive and release work therebetween.

As best shown in Fig. 29 the inner ring 228 of each of the circular frame members has an inclined face 231, and each of the pressure rings 233 has a similarly inclined face 238 for cooperation therewith. The inclined face 238 of the pressure ring 233 is provided with a rubber liner 243 back of which is an expansile fluid duct 24| of the character heretofore described. Adhesive is applied to the surfaces of juncture between the annular frame member 221 and the underlying material of the inner wall 225, and then with the pressure ring properly adjusted the expansile fluid duct 24| is placed under pressure to exert force against the inner ring of the annular frame member in a direction substantially normal to the inclined face 231 of the ring. As a result of the pressure created by the fluid duct 24|, the inner wall 225 braced -by the solid mandrel 232 acts as a circular wedge against which the circular frame member 221 Iis driven. As a result the circular frame members 221 are pressed tightly against the inner wall 225, the pressure tof 14 being sustained until the intervening glue sets to make a permanent bond.

It will be noted in Fig. 28 that the smaller end of the inner wall 225 is cylindrical rather than conical. To create the required pressure for forming an adhesive bond between this cylindrical portion of the inner wall and a surrounding circumferential frame member or ring 2&2; we provide an inner pressure ring 243 having a fluid duct 245 for radially outward expansion. r"ihe pressure ring 243 is reinforced by a ring 246 of angle-iron and is supported by radial arms 221 that are det'achably mounted by bolts 248 on the frames 236.

After fabrication is completed to the stage indicated in, Fig. 28, a final ring 25B is added to the structure in the manner indicated in Fig. 30, this final ring having a rearwardly presented groove 25| that functions in the subsequent mounting of the completed unit on the airplane. In. prepara tion for mounting the ring 252 on the inner wall 225 a special mandrel is employed comprising a spindle 252 carrying an inner member 253 and an outer member 255. The inner member 253 has a circumferential flange 255i with a conical circumferential surface complementary to the conical configuration of the inner wall 225 and the outer member 255 carries a ring 251 of a configuration complementary to the grooves 25E of the ring 25E. After glue has been applied, the frame ring 259 is forced toward the mandrel ring 251 by the action of an expansile duct 258 in a pressure ring 260, the pressure ring Ztl) being carried by arms 235 from the surrounding frames 236.

The advantages of employing an expansile uid duct in combination with longitudinal and circumferential pressure members may be noted as follows: l

(1) Pressure for holding surfaces together may be created quickly since relatively small volumes of the pressure medium are required.

(2) Higher `pressures may be created in tubes 'of smaller cross section than can be safely devel oped in pressure tanks of relatively large diameter.

(3) The rupture of an expansile duct of small cross section containing gaseous fluid under high pressure is not a serious matter, whereas` the rupture of a large tank of compressible fluid under the same pressure would be a serious hazard.

(4) The employment of the expansile iiuid -`ducts makes it possible to restrict the pressure for gluing operations to the Zones of glue application. AIt is not necessary to place extensive areas under pressure.`

(5) The employment of a number of independent fluid. expansile ducts for a relatively large assembly makes it possible to place the assembly under pressure progressively. Fluid under presn sure may be admitted to the individual expansile ducts as fast as the corresponding pressure rings or other pressure members are fixed in place.

(6) The employment of the expansile fluid ducts to create pressure at the Zones of juncture 'makes it possible to heat the pressure fluid and thereby simultaneously transfer heat to the zones of juncture. l

('1) The uid pressure in the expansile ducts lmay be measured and controlled at a remote station. Thus an assembly may be placed in a heat ing chamber and the pressure in the various expansile ducts of the assembly may be controlled by an opera-tor outside the heating chamber.

(8) When an lassembly including a number of expansile ducts is placed in a heating chamber, the rise in temperature may tendto cause the Sil-41535288 l pressure rings or other pressure members to' expand, but such a tendency is compensated at least inqpart by the tendency'for. the. rise in temperature to cause the pressure iluid to expand simultaneously.

. (9)` If the expansion of a pressure ring does causea dropin the uid pressurenotwithstanding the increase in temperature of the lluid, in operator,` at a remote point may observe the drop in pressure andy restore the pressure by supplying additional fluid to the expansile ducts.

(109 A circumferential' pressure duct does not cause friction or tend to creep circumferentiailly in the manner of a metalband that isplacedy under tension to create thed-esired radial pressure.

(11)v The radial pressure created' by a circumferential pressureI duct can4 be measured accurately, Whereas the radial pressure createdby a circumferential member cannot in` practice be measured;

(12)' Because of friction sionL member does notl create uniform radial pressure, Whereas au circumferential pressure duct exerts the same radial pressure at all circumlferential points.

(13 A circumferential! tension member cannotbe used in a. satisfactory manner for creating radial pressure on. an elliptical or oval body, because nearly all of. the. radialy pressure will be exerted across the the body. A circumferential( pressure duct in combination with a rigid-` nonciiicular pressure member or girth means aroundV the body may be employedy to. produce substantially the same pressure across the minor cross-sectional axis as across. the major cross-sectional` aXisof the non-circular body.

(14.9` Allci the expansile ducts of a jig: assembly may bel interconnected or connected. to a common source or manifold, thereby making. all of. the compressed fluid continuous sov that a minor leak at any point Will not. cause serious iocal lowering; @i pressure.

(15) The tightening of a circumferential tene sion means. tol attain. adequate radialA .compresrequires tedicusand time-consuming manip.,- ulatiom Whereas pressure may be created. immediately in.v a pressure duct by merely turning, a valve.

The description` herein` in specic detail; of, the preferred practices ci our invention will suggest a circumferential ten7` major c11oss,-sect-ional axis of to those skilled. in the. art. various?. changes and l modifications in the apparatus under our, basic inventive concept, and We reserve the rightto all such.. changesV and` modifications that lie within the scope of, our appendedV claims.

We claim as our invention:

l. Iny an apparatus for assembling relatively longv hollow structures having.l Wall material, in sheet form reinforced by` internal frameimembers, the combination of; a jig assembly of. a. length greater than thehollow structure-for positioning said frame members to. receive saidv sheet.. material Withintervening adhesive; atleastthree. supporting means for said jig assembly, some of said supporting means being movable outiov contact withy the jig assembly topermit. circumferential frameA members to be movedontoami.` along the jig assembly from. one end, thereof. for distributionl of said frame` members` therealong;vr means for expandingsaid jig assembly.- outward toreinforce said' fra-me members against inward pressure and for subsequently collapsing said jig assemblyto permit subsequent withdrawal; and means for embracing the assembly of frame members'withsurrounding sheet material to press the sheet material inwardly against the frame members while said adhesive sets.

2. Ina collapsible jig for retaining in axiallyspaced position a plurality of circumferential frame members preparatory to covering same with a wall materiaL the combination of a core; a pair of mandrel elements diametrically opposite the axis of said core and providing notches for reception of saidY circumferential frame members; means between said core and said mandrel elements` for moving at least one of said manplatesv disposed within each frame member land extending substantially transverse to. said axis ofsaid, core, each plate providing an outer periphto the inner periphery of apfor spreading the plates of each pair into pressural engagement with the. surrounding frame member.

WILLIAM L. IEWIS. FREDERIC C. PAHL.

REFERENCES CITED The followingv references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 784,909 westerling Mar. 14, 1905 1,112,686 Cunnu's Oct. 6, 1914 1,271,386 Tarbox July 2, 1918 1,312,615 Cooper Aug. 12, 1919 1,361,835 Delage Dec. 14, 1920 1,363,433 Phipps Dec. 28, 1920 1,394,726 Gilmorev Oct. 25, 1921 1,425,113 LouglceadA Aug. 8, i922 1,618,536- Junkers Feb. 22, 1927 1,720,968 Schmidt July 16, 1929 1,806,861 Owen May 26, 1931 `11,822,271) Bunch Sept. 8, 1931 11,871,982 Geyer Aug. 16, 1932 11,884,144 Norquist Oct. 25, 1932 1,932,430 Weyer-becher Oct. 31, 1933 1,954,183 Schlesinger Apr. 10, 1934 2,090,415 Homey Aug. 17, 1937 2;158,280l Klemm Aug. 1, 1939 2,252,040 Fischer-Schmutz Aug. 12, 1941 2,276,004 Vidal et al Mar. 10, 1942 2,279,820 Hamilton Apr.,14, 1942 2,287,320 Mitchell: June 23, 1942 2,308,453v Potchen et al Jan. 12, 1943 2,822,962 Dickson et al June 29, 1943 FOREIGN PATENTS Number Country Date 65,208l Germany Nov. 1, 1892 406,005 Great Britain Feb. 15, 1934 444,462 GreatBrtain Mar. 20, 1936 456,503 Great4 Britain Nov. l0, 1936 494,885 Great Britain Nov. 3, 1938 

